FR2629945A1 - Integral frame and junction box for a photovoltaic module - Google Patents

Abstract

The present invention produces a photovoltaic module 1 in which a junction box forms one piece with the frame 3 of this module. Preferably, the junction box 4 forms one piece with a frame element 5 which constitutes a part of the frame 3 of the photovoltaic module 1. This arrangement simplifies the construction of the photovoltaic module 1 and also improves its structural and electrical integrity. More importantly, this eliminates the need to place a junction box on the rear face of the photovoltaic module 1. This is particularly important when using two-faced solar cells since no area of these cells, neither on the front nor on the rear, should be covered.

Description

"SOLIDARITY FRAME AND JUNCTION BOX FOR A PHOTOVOLTAIC MODULE"
The present invention relates to a photovoltaic module and more specifically to a junction box which is integral with the frame of the photovoltaic module.

 A photovoltaic module is a device that is used to generate electrical energy from sunlight. An example of a photovoltaic module is a solar panel. Generally, a photovoltaic module uses a plurality of solar cells mounted in a frame so as to convert light energy from the sun directly into usable electricity. The solar cells can be connected to each other in a wide variety of configurations which depend on the needs of the circuit and the design of the solar panel and the solar cells themselves.

 Each photovoltaic module # which generally comprises one or two junction boxes intended to connect it to the electrical circuit. These junction boxes are placed on the rear face of the photovoltaic module and cover a portion of the rear face. An example of this arrangement is found in the Model NOM55 solar panel manufactured by Arco Solar, Inc.

 In this arrangement, these junction boxes must be permanently attached to the rear face of the solar panel and sealed vis-à-vis the environment so as to maintain the electrical integrity of the solar panel. This can be a time consuming and costly process. For example, in a module configuration that uses two glass elements, one for the superstructure and the other for the substrate, a hole must be cut or drilled through the rear substrate so that an electrical connection can be made . Another problem with placing the junction box at the back of the panel is its vulnerability during handling and mounting. Because of its location on the rear panel, the junction box serves as a convenient handle when moving the solar panel, but this increases the risk that the adhesive seal that holds the junction box to the back of the panel is accidentally broken and that this in turn leads to the destruction of the electrical integrity of the panel vis-à-vis the environment.

 Another problem linked to the location of the junction box on the rear face of the photovoltaic module lies in the fact that the junction box covers part of the rear face. This is particularly important in a solar panel in which bifacial solar cells are used. A bifacial solar cell is a cell which is activated (that is to say, which produces a continuous electric voltage and current) by a light striking either its front face or its rear face. When using bifacial solar cells in a photovoltaic module it is very important that the back side of the solar cells is not covered.

 It is the objective of this invention to produce a photovoltaic module and a junction box having improved integrity from the structural, electrical and environmental point of view, and in which all shading of the face rear of the module is minimized or eliminated.

 The present invention relates to a photovoltaic module comprising a laminate forming a solar cell intended to generate electricity, a plurality of frame elements which support the laminate forming a solar cell and a junction box intended to electrically connect the laminate forming a cell. solar circuit, the junction box forming one body with at least one of the elements of the frame. The frame formed by the elements of the frame can have any shape or size, but it is preferably rectangular. Similarly, the frame member with which the junction box is made can be any of the frame members, but it is preferably one of the shorter frame members.

 The present invention is particularly useful with photovoltaic modules which use bifacial solar cells in which overlapping of the rear face of the module must be minimized or, preferably, eliminated. Because the junction box is integral with the frame, no part of the rear face of the photovoltaic module is covered and consequently none of the solar cells is covered.

This results in an increase in the efficiency of the photovoltaic module.

 The present invention is not limited to photovoltaic modules which have bifacial solar cells, since it also improves the integrity of any photovoltaic module from the structural, electrical and vis-à-vis point of view. environment. Another advantage of the solidarity between junction box and frame of the present invention is the reduction in the total cost of the photovoltaic module due to the fact that only one junction box is used instead of two.

 The elimination of the junction box from the rear of the photovoltaic module also increases the structural, electrical and environmental integrity of the module. In the absence of a junction box on the rear face of the module, it is unlikely that a person handling the photovoltaic module accidentally breaks the seal vis-à-vis the environment and thereby alters the electrical integrity of the module.

 The frame and the junction box integral with the present invention make it easier to make the parallel and / or serial connections of the photovoltaic modules and their connection to the electrical circuit. In addition, there is no longer a need to drill a hole in the rear substrate of the laminate forming a solar cell. Instead, the electrical connection of the solar cells can be made at the edge of the laminate forming the solar cell. It is also expected that the frame element and the junction box integral with the present invention can reduce the overall cost of a photovoltaic module through the use for all modules of uniform and standardized frame parts.

 Other details, objectives and advantages of the present invention will become more readily apparent from the following description of a currently preferred practical embodiment of this invention.

A preferred concrete embodiment of the present invention is shown, only by way of example, in the accompanying drawings, among which:
Figure 1 shows a photovoltaic module according to the present invention in which the junction box is integral with the frame;
Figure 2 is a side view of part of the photovoltaic module of Figure 1, taken along line AA '.

 In general, the present invention comprises a photovoltaic module 1 comprising a laminate 2 forming a solar cell, a frame 3 and a junction box 4 forming a body with the frame 3 as shown in Figure 1. The frame 3 preferably has a rectangular shape and is composed of four elements 5 of frame. The frame 3 is typically made of a resistant but light material such as aluminum type 204 treated by anodization, but it can be made of any material capable of functioning as a frame.

 As shown in Figure 1, we see the front side of the photovoltaic module 1. There is no junction box placed on the rear face of the photovoltaic module 1. Instead, a junction box 4 is integral with an element 5 of the frame, preferably located at the top or bottom of the photo voltarque module 1. By making the junction box 4 integral with a shorter element of the frame, the quantity of material required for the junction box is reduced . However, the junction box 4 could be constituted as a unit integral with any of the elements of the frame. The junction box 4 extends over the entire width of the photovoltaic module 1, although this is not compulsory.

 There is at least a first opening 6, in the junction box 4, for a means of connection to a circuit intended to allow the photovoltaic module 1 to be connected to the electrical circuit. Preferably, the means of connection to a circuit is a wire or cable 7 which is brought through a first opening 6 located in the bottom of the junction box 4 and is connected to a terminal strip 8 located on the block of terminal 9. The wire or cable 7 may or may not be enclosed in a pipe or sheath. Preferably, the first openings 6 are dimensioned to receive cable or sheath fittings composed of a threaded sleeve and nut thus constituting a seal vis-à-vis the environment at the location first openings 6. Usually two first openings 6 are put into service, one for the positive connection to the circuit and the other for the negative connection to the circuit. All the first unused openings 6 can be closed off, preferably with plastic caps, so as to seal the junction box 4 with respect to the environment. Preferably, the first openings 6 are placed on the bottom of the one-piece junction box so as to prevent any overlapping of the front face of the module and to ensure easier access when the module is installed in a solar network.

 The terminal block 9 can extend over the entire length of the junction box 4 but it is preferable that it extends only partially over this length. The terminal block 9 is made of a non-conductive material such as bakelite and is fixed with an adhesive to the inner walls of the member 5 forming a frame and the junction box 4 integral.

 Preferably, part of the junction box 4 has been removed and replaced by a transparent cover 10 which is placed below the terminal strips 8 and the terminal block 9. The transparent cover 10 makes it possible to visually inspect the connections located on terminal block 9 for an observer located below the module without removing this cover. It is preferable to use a captive gasket 11 made of rubber so as to seal the transparent cover 10 to the junction box 4 vis-à-vis the environment and thereby prevent any entry of water or other foreign matter. which could damage the electrical connection. Because of its position, the transparent cover 10 is also provided with captive screws so as to avoid accidental loss during installation and inspection on site.

 Figure 2 shows a side view of part of the photovoltaic module 1, taken along the line AA 'of Figure 1. Preferably, the member 5 forming a frame and the integral junction box 4 have a rectangular shape with four sides. The four sides of the junction box 4 are preferably extruded in one piece or they can be assembled from four separately extruded elements provided that they constitute a sealed chamber vis-à-vis the environment.

A corner locking arrangement should be sufficient by key if separately extruded elements are used.

 Preferably, # the terminal block 9 has a shape as shown in Figure 2. As a result, the terminal strips 8 have an angled shape so as to allow easier access from below once the cover slide 10 has been removed. This configuration also allows the terminal block 9 to be easily adjusted inside the frame member and the integral junction box. As shown in Figure 2, the terminal block 9 has a plurality of holes 12 which are drilled therein just above the terminal strips 8.

The holes 12 make it possible to make an electrical connection with the solar cells 18. Preferably an insulating insert 13, such as a rubber insert of high density, is placed in the hole 12 so as to constitute a screw seal. -to the environment and to prevent the means of connection of the laminate forming a solar cell, such as the conductor 14, from coming into contact with the terminal block 9. This is necessary since the conductor 14 is generally not insulated and must be electrically insulated from the frame 3. One end of the conductor 14 is connected to a terminal strip 8 and the other end to the solar cells 18.

 At least a second opening 15 is provided in the frame element 5 so as to allow electrical connection to the solar cells 18. Preferably, the second opening 15 is not located in the same wall of the element 5 of frame than the first opening 6. It is also preferable that the second opening 15 is smaller than the hole 12.

Two perpendicular protrusions 16 and 17 extend from the wall of the frame element 5 above and below the second opening 15. These protrusions in cooperation with the wall of the frame element 5 constitute a C-shaped notch intended to receive the edge of the laminate 2 forming a solar cell.

 As shown in Figure 2, the laminate 2 forming a solar cell is that part # e of the photovoltaic module l comprising solar cells 18 interposed between two layers of glass 19. Preferably, these layers are made of glass but other transparent products can be used.

 The edge of the laminate 2 forming a solar cell comes to bear against the wall of the frame element 5 in such a way that the conductor 14 is placed above a second opening 15. The advantage of this structure lies in the fact that the conductor 14 can easily lead to the end of the laminate 2 forming a solar cell without having to drill a hole through the glass 19. Preferably, there are two conductors 14, one for positive connection to solar cells 18 and the other for negative connection to solar cells 18. Similarly, there are two second openings 15, one for positive connection and the other for negative connection .A seal gasket 20, placed between the laminate 2 forming a solar cell and the projections 16 and 17, helps to seal vis-à-vis the environment the laminate 2 forming a solar cell and the second opening 15. It can also be used pad for laminate 2 forming a solar cell. Preferably the gasket 20 is an EPDM gasket gasket.

 The conductor 14 can be fixed to the terminal strip 18 by a variety of known means such as soldering, provided that a good electrical connection is made. Similarly, the cable 7 can be fixed to the terminal strip 8 by a variety of known means comprising a screw 21.

Additional terminal strips 8 can be placed on the terminal block 9 so as to allow additional electrical connections and assemblies, if necessary. For example, it may be necessary due to the configuration of the circuit, to have a neutral terminal or some sort of protective mounting such as a diode connected to the solar cells 18. These additional strips 8 of terminals provide this flexibility.

 In a concrete embodiment of the present invention, the frame element 5 and the junction box measure 17.18 x 1.25 cm x 5.08 cm (17 inches x 1.25 inches x 2.0 inches). Terminal block 9 measures 12.7 cm x 2.69 cm x 4.60 cm (5.0 inches x 1.06 inches x 1.81 inches), with the top only 0.97 cm (0.38 inch) in width. The transparent cover 10 of this concrete embodiment measures only 15.24 cm x 2.54 cm (6.0 inches x 1.0 inches). These dimensions are provided only as an example of the size of the frame element 5 and the integral junction box used with a photovoltaic module which measures 43.18 cm x 101.6 cm.

 While a bifacial photovoltaic module according to the present invention has a 45% increase in the unlit or subtended border area and a corresponding decrease in yield (based on the subtended area) of 4%, it has a net increase in efficiency due to the elimination of the covering of the rear face of the module by the junction box. In existing photovoltaic modules, two junction boxes and the connections associated with the cables are mounted on the rear face of the photovoltaic module, covering the rear faces of several solar cells. Generally, the sum of the areas of these devices is approximately 150 cm2 or approximately 3.5% of the model's subtended area. The overlap of these areas results in a reduction in energy production and efficiency, This decrease in yield, however, will be greater than the area covered. A careful estimate suggests a decrease coefficient of 1.5. For the surface of 3.5% covered, this results in a decrease in yield of 5.3%, which is greater than the loss of 4% due to the increase in the subtended area of the module n; 'otovoltaic of the present invention.

 The increase resulting from the yield due to the non-covering of this zone of the rear face is particularly important because in many applications, the area subtended by a photovoltaic module is not as important as its energy production. As a result, a module that produces 5.3 more energy with the same number of solar cells would be preferred to a smaller module with lower energy production.

 Although a currently preferred concrete embodiment of practicing the invention has been shown and described in detail in conjunction with the accompanying drawings, this invention can be concretely achieved in another way while remaining within the scope of claims that follow.

Claims (5)

 1. Photovoltaic module (1) comprising a laminate (2) forming a solar cell intended to generate electricity, a plurality of elements (5) of the frame which support the laminate (2) forming a solar cell and a box (4) junction, characterized in that the junction box is one with one of the elements (5) of the frame and is provided with a terminal block (9) made of an insulating material and provided with an opening ( 12) which is arranged there aligned with an opening (15) formed in the particular element (5) of the frame; a conductive terminal strip (8) disposed on said terminal block (9) near said opening (12) formed in the block (9); a conductor (14) electrically connected to said laminate (2) forming a solar cell; said terminal strip (8) and an electrically insulating sealing material (12) filling said openings so as to constitute a sealing and insulating said conductor from said frame and a cable (7) electrically connecting said terminal strip to a circuit which uses the electricity generated by said photovoltaic module.  2. Photovoltaic module according to claim 1 characterized in that the junction box (4) is provided with an opening (6) formed in the particular element (5) of the frame intended for the cable (7) and a seal is formed between the opening (6) and the cable (7).  3. Photovoltaic module according to claim 1 characterized in that the junction box is provided with a sealed transparent plate forming a cover so as to allow the terminal strip (8) 'to be observed at any time without affecting the junction box sealed (4).  4. Photovoltaic module according to claim 1 characterized in that the laminate (2) forming a cell is bifacial to generate electricity to spread from sunlight striking the two faces of the laminate forming a solar cell and the junction box neither covers nor neither side.  5. Photovoltaic module according to claim 1 characterized in that the elements (5) of the frame form a rectangular frame and the junction box (4) is one with one of the shortest elements (5) of the frame.